Modeling directed scale-free object relationships

ABSTRACT

Systems and methods for generating models of directed scale-free object relationships are described. In one aspect, a sequence of random numbers is generated. Individual ones of these random numbers are then selected over time to generate the directed scale-free object relationships as a graph based on sequences of in-degrees and out-degrees.

RELATED APPLICATION

This application claims priority to U.S. provisional application Ser. No. ______, titled “Generating Models for Directed Scale-Free Inter-Object Relationships”, filed on Apr. 18, 2003, and hereby incorporated by reference.

TECHNICAL FIELD

The invention pertains to generating models for growth and distribution of directed scale-free object relationships.

BACKGROUND

Many new processes for generating distributions of random graphs have been introduced and analyzed, inspired by certain common features observed in many large-scale real-world graphs such as the “web graph”, whose vertices are web pages with a directed edge for each hyperlink between two web pages. For an overview see the survey papers [2] and [15] of the Appendix. Other graphs modeled are the “internet graph” [18], movie actor [28] and scientific [25] collaboration graphs, cellular networks [21], and so on.

In addition to the “small-world phenomenon” of logarithmic diameter investigated originally in the context of other networks by Strogatz and Watts [28], one of the main observations is that many of these large real-world graphs are “scale-free” (see references [5, 7, 24] of the Appendix), in that the distribution of vertex degrees follows a power law, rather than the Poisson distribution of the classical random graph models G(n, p) and G(n, M) [16, 17, 19], see also [9]. Many new graph generators have been suggested to try to model such scale-free properties and other features, such as small diameter and clustering, of real-world events, phenomena, and systems that exhibit dynamically developing object relationships such as that presented by the Worldh a Wide Web (WWW). Unfortunately, such existing generators produce models that are either completely undirected or, at most, semi-, or uni-directional (i.e., either in-degrees or out-degrees are treated, but not both simultaneously), and/or have a statically predetermined degree distribution.

In light of this, existing techniques for generating graphs do not provide realistic treatments of dynamically generated scale-free graphs with directed object relationships (i.e., link(s) from one object to another) that develop in a way depending on both links out-of and into an object. As such, conventional generation techniques do not adequately represent specific or fully modeled simulations of scale-free, directed object relationships that may exist in nature and/or other dynamic environments such as the WWW.

In view of these limitations, systems and methods for generating models of directed scale-free graphs or dynamic communities of relationships (e.g., network topologies) are greatly desired. Such generators could be used, e.g., to generate sample directed network topologies on which directed internet routing protocols are tested, or to generate sample web graphs on which search algorithms are tested.

SUMMARY

Systems and methods for generating models of directed scale-free object relationships are described. In one aspect, a sequence of random numbers is generated. Individual ones of these random numbers are then selected over time to generate the directed scale-free object relationships as a graph based on sequences of in-degrees and out-degrees.

BRIEF DESCRIPTION OF THE DRAWINGS

The following detailed description is given with reference to the accompanying figures. In the figures, the left-most digit of a component reference number identifies the particular figure in which the component first appears.

FIG. 1 is a block diagram of an exemplary computing environment within which systems and methods for generating models of directed scale-free object relationships may be implemented.

FIG. 2 is a block diagram that shows further exemplary aspects of system memory of FIG. 1, including application programs and program data for generating models of directed scale-free object relationships.

FIG. 3 shows an exemplary network of directed object relationships.

FIG. 4 shows an exemplary procedure to generate a model of directed scale-free object relationships.

DETAILED DESCRIPTION

Overview

The following systems and methods generate directed scale-free modeling of object relationships. This is accomplished through the simultaneous treatment of both in-degrees and out-degrees (bidirectional) to provide a very natural model for generating graphs with power law degree distributions. Depending on the characteristics of the entity or the abstraction being modeled, power laws can be different for in-degrees and out-degrees. Such modeling is consistent with power laws that have been observed, for example, in nature and in technological communities (e.g., directed hyperlinks among web pages on the WWW, connections among autonomous systems on the AS internet, connections among routers on the internet, etc.).

Exemplary Operating Environment

Turning to the drawings, wherein like reference numerals refer to like elements, the invention is illustrated as being implemented in a suitable computing environment. Although not required, the invention is described in the general context of computer-executable instructions, such as program modules, being executed by a personal computer. Program modules generally include routines, programs, objects, components, data structures, etc., that perform particular tasks or implement particular abstract data types.

FIG. 1 illustrates an example of a suitable computing environment 120 on which the subsequently described systems, apparatuses and methods to generate directed scale-free network topologies may be implemented. Exemplary computing environment 120 is only one example of a suitable computing environment and is not intended to suggest any limitation as to the scope of use or functionality of the systems and methods described herein. Neither should computing environment 120 be interpreted as having any dependency or requirement relating to any one or combination of components illustrated in computing environment 120.

The methods and systems described herein are operational with numerous other general purpose or special purpose computing system environments or configurations. Examples of well known computing systems, environments, and/or configurations that may be suitable include, but are not limited to, hand-held devices, symmetrical multi-processor (SMP) systems, microprocessor based or programmable consumer electronics, network PCs, minicomputers, mainframe computers, portable communication devices, and the like. The invention may also be practiced in distributed computing environments where tasks are performed by remote processing devices that are linked through a communications network. In a distributed computing environment, program modules may be located in both local and remote memory storage devices.

As shown in FIG. 1, computing environment 120 includes a general-purpose computing device in the form of a computer 130. Computer 130 includes one or more processors 132, a system memory 134, and a bus 136 that couples various system components including system memory 134 to processor 132. Bus 136 represents one or more of any of several types of bus structures including a memory bus or memory controller, a peripheral bus, an accelerated graphics port, and a processor or local bus using any of a variety of bus architectures. By way of example, and not limitation, such architectures include Industry Standard Architecture (ISA) bus, Micro Channel Architecture (MCA) bus, Enhanced ISA (EISA) bus, Video Electronics Standards Association (VESA) local bus, and Peripheral Component Interconnects (PCI) bus also known as Mezzanine bus.

Computer 130 typically includes a variety of computer readable media. Such media may be any available media that is accessible by computer 130, and it includes both volatile and non-volatile media, removable and non-removable media. In FIG. 1, system memory 134 includes computer readable media in the form of volatile memory, such as random access memory (RAM) 140, and/or non-volatile memory, such as read only memory (ROM) 138. A basic input/output system (BIOS) 142, containing the basic routines that help to transfer information between elements within computer 130, such as during start-up, is stored in ROM. RAM typically contains data and/or program modules that are immediately accessible to and/or presently being operated on by processor(s) 132.

Computer 130 may further include other removable/non-removable, volatile/non-volatile computer storage media. For example, FIG. 1 illustrates a hard disk drive 144 for reading from and writing to a non-removable, non-volatile magnetic media (not shown and typically called a “hard drive”), a magnetic disk drive 146 for reading from and writing to a removable, non-volatile magnetic disk 148 (e.g., a “floppy disk”), and an optical disk drive 150 for reading from or writing to a removable, non-volatile optical disk 152 such as a CD-ROM/R/RW, DVD-ROM/R/RW/+R/RAM or other optical media. Hard disk drive 144, magnetic disk drive 146 and optical disk drive 150 are each connected to bus 136 by one or more interfaces 154.

The drives and associated computer-readable media provide nonvolatile storage of computer readable instructions, data structures, program modules, and other data for computer 130. Although the exemplary environment described herein employs a hard disk, a removable magnetic disk 148 and a removable optical disk 152, it should be appreciated by those skilled in the art that other types of computer readable media which can store data that is accessible by a computer, such as magnetic cassettes, flash memory cards, digital video disks, random access memories (RAMs), read only memories (ROM), and the like, may also be used in the exemplary operating environment.

A number of program modules may be stored on the hard disk, magnetic disk 148, optical disk 152, ROM 138, or RAM 140, including, e.g., an operating system (OS) 158 to provide a runtime environment, one or more application programs 160, other program modules 162, and program data 164.

A user may provide commands and information into computer 130 through input devices such as keyboard 166 and pointing device 168 (such as a “mouse”). Other input devices (not shown) may include a microphone, joystick, game pad, satellite dish, serial port, scanner, camera, etc. These and other input devices are connected to the processing unit 132 through a user input interface 170 that is coupled to bus 136, but may be connected by other interface and bus structures, such as a parallel port, game port, or a universal serial bus (USB).

A monitor 172 or other type of display device is also connected to bus 136 via an interface, such as a video adapter 174. In addition to monitor 172, personal computers typically include other peripheral output devices (not shown), such as speakers and printers, which may be connected through output peripheral interface 176.

Computer 130 may operate in a networked environment using logical connections to one or more remote computers, such as a remote computer 178. Remote computer 178 may include many or all of the elements and features described herein relative to computer 130. Logical connections shown in FIG. 1 are a local area network (LAN) 180 and a general wide area network (WAN) 182. Such networking environments are commonplace in offices, enterprise-wide computer networks, intranets, and the Internet.

When used in a LAN networking environment, computer 130 is connected to LAN 180 via network interface or adapter 184. When used in a WAN networking environment, the computer typically includes a modem 186 or other means for establishing communications over WAN 182. Modem 186, which may be internal or external, may be connected to system bus 136 via the user input interface 170 or other appropriate mechanism.

Depicted in FIG. 1, is a specific implementation of a WAN via the Internet. Here, computer 130 employs modem 186 to establish communications with at least one remote computer 178 via the Internet 188.

In a networked environment, program modules depicted relative to computer 130, or portions thereof, may be stored in a remote memory storage device. Thus, e.g., as depicted in FIG. 1, remote application programs 190 may reside on a memory device of remote computer 178. It will be appreciated that the network connections shown and described are exemplary and other means of establishing a communications link between the computers may be used.

FIG. 2 is a block diagram that shows further exemplary aspects of system memory 134 of FIG. 1, including application programs 160 and program data 164. Application programs 160 include, for example, a Directed Scale-Free Object Relationship Network Generating Module 202 to generate a Directed Scale-Free Graph 204 (hereinafter often referred to as the “graph”). Each graph 204 represents vertices and edges between respective vertices that have been added to the graph by the network generating module 202 during discrete iterative operations that are performed over time t. Before turning to more detailed aspects of the algorithms used to generate the graph 204, exemplary structure and elements of a graph 204 are described in reference to graph 204(a).

Graph 204(a) is represented as a matrix, wherein each horizontal row i and vertical column j of the matrix corresponds to a respective vertex, or node (i.e., node, through node_(N)). Thus, i=1 . . . N, and j=1 . . . N. (Hereinafter, the terms node and nodes are often used interchangeably with the terms vertex and vertices). To grow graph 204(a) from some number of nodes to a greater number of nodes, the network generating module 202 adds a node to the graph 204(a). This means that a row and a column representing the new node are added to the graph 204(a). The (i,j) element E(i,j) of the graph 204(a) represents the number of directed edges or connections from node i to node j, modeling e.g., the number of hyperlinks from web page i to web page j, or a directed transfer of E(i,j) objects or characteristics from entity i to entity j (such as the transfer of money and goods between a merchant and a buyer), and/or the like.

In the representation 204(a), we have adopted the convention that edge direction is evaluated from the row-node to the column-node.

We now describe the edge E(i,j) values of graph 204(a) in view of network 300 of FIG. 3, which shows the exemplary network 300 of directed object relationships. In this exemplary network, objects 302-1, 302-2, and 302-3 have at least one edge 304 (i.e., one or more edges 304-1 through 304-N) to/from another object. For example, object 302-1 (FIG. 3) shows a looping edge 304-1 that indicates that the object has a relationship to itself (for example, a web page having a hyperlink to a point inside itself).

Referring to FIG. 2, such a looping edge is also represented in graph 204(a) at the edge value that corresponds to the intersection between row-Node, and column-Node, (i.e., E(1,1)=1). This indicates that Node, has a single relationship to itself This type of edge is called a “loop”.

In this implementation, the module 202 may generate (self-)loops in the graph 204. However, the generating module 202 can be configured not to generate loops to model systems without self-loops.

In another example to represent edges 304 of FIG. 3 with a directed scale-free graph 204(a) of FIG. 2, note that object 302-1 of FIG. 3 has three (3) edges 304-2 through 304-4 to node 302-2. In particular, the intersection of row-Node₁ with column-Node₂ (i.e., E(1,2)) shows a value of 3, which is representative of the relationship between object 302-1 of FIG. 3 to object 302-2. This type of edge is called a “multiple edge”, which in general refers to two or more edges from a particular object Nodes to a different object Node_(j). In this implementation, the module 202 may generate multiple edges in the graph 204. However, in another implementation, the generating module 202 can be configured not to generate multiple edges, to model systems in which there are only single edges.

Although network 300 of FIG. 3, and graph 204(a) of FIG. 2 respectively represent/map only 3 nodes/objects, it can be appreciated that the complexity and number of objects represented/mapped by the exemplary network 300 and graph 204(a), are exemplary and could represent/map any number of objects of any complexity.

We now describe the algorithms used by the generating module 202 to generate directed scale-free object relationships in further detail.

Generating Directed Scale-Free Object Relationships

Referring to FIG. 2, the generating module 202 introduces random and probabilistic aspects during graph 204 generation to simulate dynamically created objects (e.g., web pages, etc.) and relationships between them (e.g., hyperlinks, etc.) that is/are often observed, for example, in technological (e.g., the web), cultural, natural, and/or the like, environments. Such a random aspect is obtained via iterative generating module 202 requests over time t for respective random number(s) 206 from the random number generating module (RNG) 208. The RNG 208 can be a standalone module, or a service provided by a computer program module such as the OS 158 (FIG. 1).

Some of the random numbers 206 will be required to lie between 0 (zero) and 1 (one). For each of these random numbers 206, the network generating module 202 uses the random number 206 to determine one of three possibilities, labeled (A), (B) and (C), depending on whether the random number lies between 0 (zero) and α, α and α+β, or α+β and α+β+γ, respectively. The parameters α, β and γ are non-negative real numbers that when added together equal one (1), i.e., α+β+γ=1. These parameters stored as respective portions of the configuration data 210. The parameters α, β and γ can be selected/determined in different manners, for example, manually preconfigured by a system administrator, programmatically configured in view of environmental measurements, etc. This allows for considerable flexibility to customize the model generating process to simulate structural and object relationships of various types of measured environments.

When the generating module 202 maps the random number 206 to the range [0, α], the generating module 202 augments the graph 204 by adding a vertex and an edge from the new vertex into an existing (old) vertex. When the generating module 202 maps the random number 206 to the range [α, α+β], the generating module 202 augments the graph 204 by connecting two old vertices (i.e., a vertex is not added, but one of the E(i,j) values increases by one). When the generating module 202 maps the random number 206 to the range [α+β, α+β+γ], the generating module 202 augments the graph 204 by connecting an old vertex to a newly generated vertex. Additionally, during graph generation, the module 202 applies configurable constants δ_(in) and/or δ_(out) to introduce in-degree and out-degree shifts to the graph.

The degree shift, δ_(in) or δ_(out), is a non-negative parameter added to the in-degree or out-degree of a vertex, respectively. The degree shift is added before applying any other rules which are used to choose random vertices.

In light of the above, let G₀ be any fixed initial directed graph 204, for example, a single vertex (i.e., Node₁) without edges (i.e., E(1,1)=0), and let t₀ be the number of edges of G₀. The generating module 202 always adds one edge per iteration, and sets G(t₀)=G₀, so at time t the graph G(t) has exactly t edges, and a random number n(t) of vertices. For purposes of discussion, number(s) of edges and vertices, as well as other intermediate parameters and calculations are represented by respective portions of “other data” 212.

In the operation of the generating module 202, to choose a vertex v of G(t) according to d_(out)+δ_(out) means to choose v so that Pr(v=v_(i)) is proportional to d_(out)(v_(i))+δ_(out), i.e., so that Pr(v=v_(i))=(d_(out)(v_(i))+δ_(out))/(t+δ_(out)n(t)). To choose v according to d_(in)+δ_(in) means to choose v so that Pr(v=v_(j))=(d_(in)(v_(j))+δ_(in))/(t+δ_(in)n(t)). Here d_(out)(v_(i)) and d_(in)(v_(j)) are the out-degree of v_(i) and the in-degree of v_(j), respectively, measured in the graph G(t).

For t≧t₀, the generating module 202 forms G(t+1) from G(t) according the following rules:

-   (A) With probability α (see configuration data values 210), add a     new vertex v together with an edge from v to an existing vertex w,     where w is chosen according to d_(in)+δ_(in), so that Pr(w=w_(j))     ∝(d_(in)(w_(j))+d_(in)). (For instance, in a web graph, add one (1)     edge representing a hyperlink from vertex v to vertex w). The inputs     to this algorithm are n=n(t) vertices and t edges, and the outputs     are n(t+1)=n(t)+1 vertices and t+1 edges. After adding the new     vertex v=Node_(n+1), the particular existing vertex w that will     receive the edge from the new vertex v is determined as follows:     E(i,j)=E_(ij)=number of edges from vertex i to vertex j.     ${d_{i\quad n}(j)} = {\sum\limits_{i = 1}^{n}\quad E_{ij}}$     -   At this point, the generating module 202 requests an additional         random number 206 between 0 and the sum of all numbers         d_(in)(j)+δ_(in) in G(t):         ${{\sum\limits_{j = 1}^{n}\quad\left( {{d_{i\quad n}(j)} + \delta_{i\quad n}} \right)} = {{{\sum\limits_{i = 1}^{n}{\sum\limits_{j = 1}^{n}E_{ij}}} + {n\quad\delta_{i\quad n}}} = {t + {n\quad\delta_{i\quad n}}}}}\quad$     -   The range from 0 to t+δ_(in) is divided into n slots with         lengths d_(in)(j)+δ_(in), j=1, . . . , n. The random number 206         will fall into a particular slot j. At this point, the         generating module 202 sets E(n+1,j)=1. -   (B) With probability β (see configuration data values 210), add an     edge from an existing vertex v to an existing vertex w, where v and     w are chosen independently, v according to d_(out)+δ_(out), and w     according to d_(in)+δ_(in), so that Pr(v=v_(i),     w=w_(j))∝(d_(out)(v_(i))+(w_(j))+d_(in)). The inputs to this     algorithm are n=n(t) vertices and t edges, and the outputs are     n(t+1)=n(t) vertices and t+1 edges. The generating module 202     selects the particular existing vertex v that will add an edge to     vertex w by generating a random number 206 (r_(out)):     r _(out)ε[0,t+nδ _(out])     -   This range is divided into slots, with an i^(th) slot having         length d_(out)(i)+(δ_(out). The random number 206 falls into a         particular slot i; the vertex v will be Node_(i). The generating         module 202 determines the vertex w that will receive the edge by         generating a random number 206 (r_(in)) such that:         r _(in)ε[0,t+nδ _(in)]     -   This range is divided into slots, with the j^(th) slot having         length d_(in)(i)+δ_(in). The random number 206 falls into a         particular slot j; the vertex w will be Node_(j). At this point,         the generating module 202 increments E(i,j) by 1. -   (C) With probability γ (see configuration data values 210, which can     be calculated as γ=1−α−β), add a new vertex v and an edge from an     existing vertex w to v, where w is chosen according to     d_(out)+δ_(out), so that Pr(w=w_(i))∝(d_(out)(w_(i))+δ_(out)). The     inputs to this algorithm are n=n(t) vertices and t edges, and the     outputs are n(t+1)=n(t)+1 vertices and t+1 edges. After adding the     new vertex v=Node_(n+1), the particular existing vertex w that will     add an edge to the new vertex v is determined as follows: generate a     random number (r_(out)) 206 according to:     r _(out)ε[0,t+nδ _(out)]     -   This range is divided into slots, with the jth slot having         length d_(out)(i)+δ_(out). The random number 206 falls into a         particular slot i; the vertex w will be Node_(i). Thus, the         generating module 202 sets E(i,n+1)=1.

Although the generating module 202 makes no additional assumptions about the parameters, the behavior of the resulting graph is non-trivial only if certain settings of the parameters are avoided. In particular, the following parameter values can be avoided to exclude trivialities:

-   -   α+γ=0 (⇄ the graph does not grow)     -   δ_(in)+^(δ) _(out)=0 (⇄ all vertices have not in G₀ have         d_(in)=0 or do, =0)     -   αδ_(in)+γ=0 (⇄ all vertices not in G₀ have d_(in)=0)     -   γ=1 (⇄ all vertices not in G₀ have d_(in)=1)     -   γδ_(out)+α=0 (⇄ all vertices not in G₀ have d_(out)=0)     -   α=1 (⇄ all vertices not in G₀ have d_(out)=1)

In one implementation, when graph 204 represents a web graph, δ_(out) is set to 0. The motivation is that vertices added under rule (C) correspond to web pages which purely provide content; such pages do not change, are born without out-links and remain without out-links. In this implementation, vertices generated/added under rule (A) correspond to usual pages, to which links may be added later. While mathematically it may seem natural to take δ_(in)=0 in addition to δ_(out)=0, doing so would provide a model in which every page not in G₀ has either no in-links or no out-links, i.e. a trivial model.

A non-zero value of δ_(in) corresponds to insisting that a page is not considered part of the web until something points to it, for example, a search engine. This allows the generating module 202 to consider edges from search engines independently/separately from the rest of the graph, since they are typically considered to be edges of a different nature (for purposes of implementing a search algorithm, for example) than other types of edges. For the same reason, δ_(in) does not need to be an integer. The parameter δ_(out) is included to provide symmetry to the model with respect to reversing the directions of edges (swapping α with γ and δ_(in) with δ_(out)), and to further adapt the model to contexts other than that of the webgraph.

In one implementation, taking β=γ=δ_(out)=0 and α=δ_(in)=1, the generating module 202 includes a precise version of the special case of m=1 of the Barabási-Albert model [5], wherein m represents the number of new edges added for each new vertex A more general model than that so far described here, with additional parameters, can be generated by adding m edges for each new vertex, or (as in [14]) by adding a random number of new edges with a certain distribution for each new vertex. In implementing the description here, the main effect of the Barabási-Albert parameter m, namely varying the overall average degree, is achieved by varying β.

Another more general model than that so far described here, again with additional parameters, can be generated to describe systems in which different vertices have different fitnesses. For example, some web pages may be considered more fit or attractive than others, and may get more connections per unit time even if their degrees are not as high as those of less fit web pages. To model this, whenever the generating module 202 creates a new vertex v, the random number generator 208 will independently generate two random numbers λ(v) and μ(v) from some specified distributions D_(in) and D_(out), respectively, independently of each other and of all earlier choices. Then steps (A), (B) and (C) of [0041] will be modified as follows: In step (A), the existing vertex w will be chosen according to λ(w)(d_(in)+δ_(in)) so that Pr(w=w_(i))∝λ(w_(i))(d_(in)(w_(i))+δ_(in)). In step (B), the existing vertex v will be chosen according to μ(v)(d_(out)+δ_(out)), and the existing vertex w will be chosen according to λ(w)(d_(in)+δ_(in)) so that Pr(v=v_(i), w=w_(j))∝μ(v_(i))λ(w_(j))(d_(out)(v_(i))+(δ_(out))(d_(in)(w_(j))+δ_(in)). In step (C), the existing vertex w will be chosen according to μ(w)(d_(out)+δ_(out)), so that Pr(w=w_(i))∝μ(w_(i))(d_(out)(w_(i))+δ_(out)).

An Exemplary Procedure

FIG. 4 shows an exemplary procedure 400 to generate directed scale-free object relationships. For the purposes of discussion, these procedural operations are described in reference to program module and data features of FIGS. 1 and 2. At block 402, the generating module 202 configures numerical probabilities α, β, γ, and configurable in-degree and out-degree shift constants din and δ_(out). At block 404, the generating module 202 generates random numbers 206 to select successive steps (A), (B), or (C) over time to generate the directed scale-free object relationships as a graph. Further random selection of vertices to/from which directed edges are added uses preferential attachment, i.e., selection according to in/out-degree respectively, as described in (A), (B) and (C) of [0042].

CONCLUSION

The described systems and methods generate directed scale-free object relationships. Although the systems and methods have been described in language specific to structural features and methodological operations, the subject matter as defined in the appended claims is not necessarily limited to the specific features or operations described. Rather, the specific features and operations are disclosed as exemplary forms of implementing the claimed subject matter. For instance, the described systems 100 and methods 400, besides being applicable to generation of a directed scale-free model of the web (a web graph) or some portion thereof, can also used to generate customized models of many other naturally occurring (man-made and otherwise) physical and abstract object relationships.

References

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In order to find the power laws, we fix constants α, β, γ≧0 summing to 1 and δ_(in), δ_(out)≧0, and set $c_{1} = {{\frac{\alpha + \beta}{1 + {\delta_{i\quad n}\left( {\alpha + \gamma} \right)}}\quad{and}\quad c_{2}} = {\frac{\beta + \gamma}{1 + {\delta_{\quad{out}}\left( {\alpha + \gamma} \right)}}.}}$ We also fix a positive integer t₀ and an initial graph G(t₀) with t₀ edges. Let us write x_(i)(t) for the number of vertices of G(t) with in-degree i, and y_(i)(t) for the number with out-degree i.

Note that the in-degree distribution becomes trivial if αδ_(in)+γ=0 (all vertices not in G₀ will have in-degree zero) or if γ=1 (all vertices not in G₀ will have in-degree 1), while for γδ_(out)+α=0 or α=1 the out-degree distribution becomes trivial. We will therefore exclude these cases in the following theorem.

Theorem 1. Let i≧0 be fixed. There are constants p_(i) and q_(i) such that x_(i)(t)=p_(i)t+o(t) and y_(i)(t)=q_(i)t+o(t) hold with probability 1. Furthermore, if αδ_(in)+γ>0 and γ<1, then as i→∞we have p_(i)˜C_(IN)i^(−X) ^(IN) , where X_(IN)=1+1/c₁ and C_(IN) is a positive constant. If γδ_(out)+α>0 and α<1, then as i→∞we have q_(i)˜C_(OUT)i^(−X) _(OUT), with X_(OUT)=1+1/c₂ and C_(OUT) is a positive constant.

In the statement above, the o(t) notation refers to t→∞with i fixed, while a(i)˜b(i) means a(i)/b(i)→1 as i→∞.

Proof. Note first that if the initial graph has no vertices then n(t) is equal to n₀ plus a Binomial distribution with mean (α+γ)(t−t₀). It follows from the Chernoff bound that there is a positive constant c such that for all sufficiently large t we have Pr(|n(t)−(α+γ)t|≧t ^(1/2) log t)≦e ^(−c(log t)) ².  (1) In particular, the probability above is o(t⁻¹) as t→∞.

We consider how the vector (x₀(t), x₁(t), . . . ), giving for each i the number of vertices of in-degree i in the graph G(t), changes as t increases by 1. Let G(t) be given. Then with probability α a new vertex with in-degree 0 is created at the next step, and with probability γ a new vertex with in-degree 1 is created. More specifically, with probability α+β the in-degree of an old vertex is increased. In going from G(t) to G(t+1), from the preferential attachment rule, given that we perform operation (A) or (B), the probability that a particular vertex of in-degree i has its in-degree increased is exactly (i+δ_(in))/(t+δ_(in)n(t)). Since the chance that we perform (A) or (B) is α+β, and since G(t) has exactly x_(i)(t) vertices of in-degree i, the chance that one of these becomes a vertex of in-degree i+1 in G(t+1) is exactly ${\left( {\alpha + \beta} \right){x_{i}(t)}\frac{i + \delta_{i\quad n}}{t + {\delta_{i\quad n}{n(t)}}}},$ so with this probability the number of vertices of in-degree i decreases by 1. However, with probability $\left( {\alpha + \beta} \right){x_{i - 1}(t)}\frac{i - 1 + \delta_{i\quad n}}{t + {\delta_{i\quad n}{n(t)}}}$ a vertex of in-degree i−1 in G(t) becomes a vertex of in-degree i in G(t), increasing the number of vertices of in-degree i by 1. Putting these effects together, $\begin{matrix} {{\left. {{E\left( {x_{i}\left( {t + 1} \right)} \right.}{G(t)}} \right) = {{x_{i}(t)} + {\frac{\alpha + \beta}{t + {\delta_{i\quad n}{n(t)}}}\left( {{\left( {i - 1 + \delta_{i\quad n}} \right){x_{i - 1}(t)}} - {\left( {i + \delta_{i\quad n}} \right){x_{i}(t)}}} \right)} + {\alpha\quad 1_{\{{i = 0}\}}} + {\gamma\quad 1_{\{{i = 1}\}}}}},} & (2) \end{matrix}$ where we take x⁻¹(t)=0, and write 1_(A) for the indicator function which is 1 if the event A holds and 0 otherwise.

Let i be fixed. We wish to take the expectation of both sides of (2). The only problem is with n(t) in the second term on the right hand side. For this, note that from a very weak form of (1), with probability 1−o(t⁻¹) we have |n(t)−(α+γ)t|=o(t^(3/5)). Now whatever value n(t) takes we have ${\frac{\alpha + \beta}{t + {\delta_{i\quad n}{n(t)}}}\left( {j + \delta_{i\quad n}} \right){x_{j}(t)}} = {0(1)}$ for each j, so ${E\left( {\frac{\alpha + \beta}{t + {\delta_{i\quad n}{n(t)}}}\left( {j + \delta_{i\quad n}} \right){x_{j}(t)}} \right)} = {{\frac{\alpha + \beta}{t + {{\delta_{i\quad n}\left( {\alpha + \gamma} \right)}t}}\left( {j + \delta_{i\quad n}} \right){{Ex}_{j}(t)}} + {o\left( t^{{- 2}/5} \right)}}$ and, taking the expectation of both sides of (2), ${{Ex}_{i}\left( {t + 1} \right)} = {{{Ex}_{i}(t)} + {\frac{\alpha + \beta}{t + {{\delta_{i\quad n}\left( {\alpha + \gamma} \right)}t}}\left( {{\left( {i - 1 + \delta_{i\quad n}} \right){{Ex}_{i - 1}(t)}} - {\left( {i + \delta_{i\quad n}} \right){{Ex}_{i}(t)}}} \right)} + {\alpha\quad 1_{\{{i = 0}\}}} + {\gamma\quad 1_{\{{i = 1}\}}} + {{o\left( t^{{- 2}/5} \right)}.}}$ Let us write {overscore (x_(i))}(t) for the ‘normalized expectation’ Ex_(i)(t)/t, Recalling that c₁=(α+β)/(1+δ_(in)(α+γ)), we have (t+1){overscore (x _(i))}(t+1)−t{overscore (x _(i) )}( t)=c ₁((i−1+δ_(in)){overscore (x _(i−1))}(t)−(i+δ _(in)){overscore (x _(i))}(t))+α1_({i=0})+γ1_({i=1}) +o(t ^(−2/5)).  (3) Now let p⁻¹=0 and for i≧0 define p_(i) by p _(i) =c ₁ ((i−1+δ_(in))p _(i−1)−(i+δ _(in))p _(i))+α1_({i=0)}+γ1_({i=1}).  (4) First we will show that that for each i we have E(x _(i)(t))=p _(i) t+o(t ^(3/5))  (5) as t→∝; later we shall show that x_(i)(t) is concentrated around its mean, and then finally that the p_(i) follow the stated power law. To see (5), set ε_(i)(t)={overscore (x_(i))}(t)−p_(i). Then subtracting (4) from (3), (t+1)ε_(i)(t+1)−tε _(i)(t)=c ₁(i−1+δ_(in)))ε_(i−1)(t)−c ₁(i+δ _(in))ε_(i)(t)+o(t ^(−2/5)), which we can rewrite as $\begin{matrix} {{{\varepsilon_{i}\left( {t + 1} \right)} = {{\frac{t - {c_{1}\left( {i + \delta_{i\quad n}} \right)}}{t + 1}{\varepsilon_{i}(t)}} + {\Delta_{i}(t)}}},} & (6) \end{matrix}$ where Δ_(i)(t)=c₁(i−1+δ_(in)(t)/(t+1)+o(t^(−7/5)).

To prove (5) we must show exactly that ε_(i)(t)=o(t^(−2/5)) for each i. We do this by induction on i; suppose that i≧0 and ε_(i−1)(t)=o(t^(−2/5)), noting that ε⁻¹(t)=0, so the induction starts. Then Δ_(i)(t^(7/5)), and from (6) one can check (for example by solving this equation explicitly for ε_(i)(t) in terms of Δ_(i)(t)) that ε_(i)(t)=o(t^(−2/5)). This completes the proof of (5).

Next we show that, with probability 1, we have x _(i)(t)/t→p _(i),  (7) as in the statement of the theorem. To do this we show concentration of x_(i)(t) around its expectation using, as usual, the Azuma-Hoeffding inequality [4, 20] (see also [10]). This can be stated in the following form: if X is a random variable determined by a sequence of n choices, and changing one choice changes the value of X by at most θ, then $\begin{matrix} {{\Pr\left( {{{X - {EX}}} \geq x} \right)} \leq {2{\mathbb{e}}^{- {\frac{x^{2}}{2n\quad\theta^{2}}.}}}} & (8) \end{matrix}$ To apply this let us first choose for each time step which operation (A), (B) or (C) to perform. Let A be an event corresponding to one (infinite) sequence of such choices. Note that for almost all A (in the technical sense of probability 1), the argument proving (5) actually gives E(x _(i)(t)|A)=p _(i) t+o(t).  (9)

Given A, to determine G(t) it remains to choose at each step which old vertex (for (A) or (C)), or which old vertices (for (B)) are involved. There are at most 2t old vertex choices to make. Changing one of these choices from v to v′, say, only affects the degrees of v and v′ in the final graph. (To preserve proportional attachment at later stages we must redistribute later edges among v and v′ suitably, but no other vertex is affected.) Thus x_(i)(t) changes by at most 2, and, applying (8), we have Pr(|x _(i)(t)−E(x _(i)(t)|A)|≧t ^(3/4) A)≦2e ^(−{square root}{square root over (t)}/16). Together with (9) this implies that (7) holds with probability one, proving the first part of the theorem. (Note that with a little more care we can probably replace (7) with x_(i)(t)=p_(i)t+O(t^(1/2) log t). Certainly our argument gives an error bound of this form in (5); the weaker bound stated resulted from replacing t^(1/2) log t in (1) by o(t^(3/5)) to simplify the equations. However the technical details leading to (9) may become complicated if we aim for such a tight error bound.)

We now determine the behaviour of the quantities p_(i) defined by (4).

Assuming γ<1, we have α+β>0 and hence c₁>0, so we can rewrite (4) as $\begin{matrix} {{{This}\quad{gives}\quad p_{0}} = \begin{matrix} {{\left( {i + \delta_{i\quad n} + c_{1}^{- 1}} \right)p_{i}} = {{\left( {i - 1 + \delta_{i\quad n}} \right)p_{i - 1}} + {{c_{1}^{- 1}\left( {{\alpha\quad 1_{\{{i = 0}\}}} + {\gamma 1}_{\{{i = 1}\}}} \right)}.}}} \\ {{\alpha/\left( {1 + {c_{1}\delta_{i\quad n}}} \right)},{p_{1} = {\left( {1 + \delta_{i\quad n} + c_{1}^{- 1}} \right)^{- 1}\left( {\frac{{\alpha\delta}_{i\quad n}}{1 + {c_{1}\delta_{i\quad n}}} + \frac{\gamma}{c_{1}}} \right)\quad{and}}},{{{for}\quad i} \geq 1},} \\ {p_{i} = {{\frac{\left( {i - 1 + \delta_{i\quad n}} \right)_{i - 1}}{\left( {i + \delta_{i\quad n} + c_{1}^{- 1}} \right)_{i - 1}}p_{1}} = {\frac{\left( {i - 1 + \delta_{i\quad n}} \right)!}{\left( {i + \delta_{i\quad n} + c_{1}^{- 1}} \right)!}\frac{\left( {1 + \delta_{i\quad n} + c_{1}^{- 1}} \right)!}{\delta_{i\quad n}!}{p_{1}.}}}} \end{matrix}} & (10) \end{matrix}$ Here, for x a real number and n an integer we write (x)_(n) for x(x−1) . . . (x−n+1). Also, we use x! for Γ(x+1) even if x is not an integer. It is straightforward to check that the formulae we obtain do indeed give solutions. One can check that Σ_(i=0) ^(∞)p_(i)=α+β; there are (α+γ+o(1))t vertices at large times t.

From (10) we see that as i→∞ we have p_(i)˜C_(IN)i^(−x) _(IN) with x _(IN)=((δ_(in) +c ₁ ⁻¹)˜(−1+δ_(in)=)1+1/c ₁, as in the statement of the theorem.

For out-degrees the calculation is exactly the same after interchanging the roles of α and γ and of δ_(in) and δ_(out). Under this interchange c₁ becomes c₂, so the exponent in the power law for out-degrees is x_(OUT)=1+1/c₂, as claimed. □

We now turn to more detailed results, considering in- and out-degree at the same time. Let n_(ij)(t) be the number of vertices of G(t) with in-degree i and out-degree j.

Theorem 2. Assume the conditions of Theorem 1 hold, that α, γ<1, and that αδ_(in)+γδ_(out)>0. Let i, j≧0 be fixed. Then there is a constant f_(ij) such that n_(ij)(t)=f_(ij)t+o(t) holds with probability 1. Furthermore, for j≧1 fixed and i→∞, f_(ij)˜C_(j)i^(−X′) ^(IN) ,  (11) while for i≧1 fixed and j→∞, f_(ij)˜D_(i)j^(−X′) ^(OUT) ,  (12) where the C_(j) and D_(i) are positive constants, and X′ _(IN)=1+1/c ₁ +c ₂ /c ₁{δ_(out)+1_((γδ) _(out)=0}) and X′ _(OUT)=1+1/c ₂ +c ₁ /c ₂(δ_(IN)+1_({αδ) _(in) ₌₀}

Note that Theorem 2 makes statements about the limiting behaviour of the f_(ij) as one of i and j tends to infinity with the other fixed; there is no statement about the behaviour as i and j tend to infinity together in some way.

The proof of Theorem 2 follows the same lines as that of Theorem 1, but involves considerably more calculation, and is thus given in Appendix B. The key difference is that instead of (10) we obtain a two dimensional recurrence relation (13) whose solution is much more complicated.

Before discussing the application of Theorems 1 and 2 to the web graph, note that if δout=0 (as we shall assume when modelling the web graph), vertices born with out-degree 0 always have out-degree 0. Such vertices exist only if γ>0. Thus γδ_(out)0 is exactly the condition needed for the graph to contain vertices with non-zero out-degree which were born with out-degree 0. It turns out that when such vertices exist they dominate the behaviour of f_(ij) for j>0 fixed and i→∞. A similar comment applies to αδ_(in) with in- and out-degrees interchanged. If αδ_(in)=0 then every vertex not in G₀ will have either in- or out-degree 0.

Note also for completeness that if γδ_(out)>0 then (11) holds for j=0 also. If γ=0 then f_(i0)=0 for all i. If γ>0 but δ_(out)=0, then among vertices with out-degree 0 (those born at a type (C) step), the evolution of in-degree is the same as among all vertices with non-zero out-degree taken together. It follows from Theorem 1 that in this case f_(i0)˜C₀i^(−X) ^(IN) .

Particular Values

An interesting question is for which parameters (if any) our model reproduces the observed power laws for certain real-world graphs, in particular, the web graph.

For this section we take δ_(out)=0 since this models web graphs in which there are content-only pages. We assume that α>0, as otherwise there will only be finitely many vertices (the initial ones) with non-zero out-degree. As before, let c₁=(α+β)/(1+δ_(in)(α+γ)) and note that now c₂=1−α. We have shown that the power-law exponents are X _(IN)=1+1/c ₁ for in-degree overall (or in-degree with out-degree fixed as 0), ti X _(OUT)=1+1/c ₂ for out-degree overall, and that if δ_(in)>0 we have exponents X′ _(IN)=+1/c ₁ +c ₂ /c ₁ for in-degree among vertices with fixed out-degree j≧1, and X′ _(OUT)=1+1/c ₂+δ_(in) c ₁ /c ₂ for out-degree among vertices with fixed in-degree i≧0.

For the web graph, recently measured values of the first two exponents [13] are X_(IN)=2.1 and X_(OUT)=2.7. (Earlier measurements in [3] and [23] gave the same value for X_(IN) but smaller values for X_(OUT).) Our model gives these exponents if and only if c₂0.59, so α=0.41, and c₁=1/1.1, so $\delta_{i\quad n} = {\frac{{{1 \cdot 1}\left( {\alpha + \beta} \right)} - 1}{1 - \beta}.}$ This equation gives a range of solutions: the extreme points are δ_(in)=0,β=0.49, γ=0.1 and δ_(in)=0.24, β=0.59, γ=0.

As a test of the model one could measure the exponents X_(IN)′ and X_(OUT)′ (which may of course actually vary when the fixed out-/in-degree is varied). We obtain 2.75 for X_(IN)′ and anything in the interval [2.7, 3.06] for X_(OUT)′.

Appendix B

In this appendix, we give the proof of Theorem 2. Arguing as in the proof of Theorem 1 we see that for each i and j we have n_(ij)(t)/t→f_(ij), where the f_(ij) satisfy f _(ij) =c ₁(i−1+δ_(in))f _(i=1,j) −c ₁(i+δ _(in))f _(ij) +c ₂(j−1+δ_(out))f _(ij−1) −c ₂(j+δ _(out))f _(ij)+α1_({i=0,j=1})+γ1_({i=1,j=0}).  (13) Of course we take f_(ij) to be zero if i or j is −1. Note that a vertex may send a loop to itself, increasing both its in- and out-degrees in one step. While this does complicate the equations for E(n_(ij)(t)), it is easy to see that for fixed i and j the effect on this expectation is o(t), so (13) holds exactly.

We start by finding an expansion for f_(ij) when i→∞ with j fixed.

The recurrence relation (13) is of the form L(f)=α1_({i=0,j=1})+γ1_({i=1,j=0}) for a linear operator L on the two-dimensional array of coefficients f_(ij). It is clear from the form of L that there is a unique solution to this equation. By linearity we can write j _(ij) =g _(ij) +h _(ij) where L(g)=α1_({i=0,j=1})  (14) and L(h)=γ1_({i=1,j=0})  (15)

Let us first consider g. As α, γ21 1 we have c₁, c₂>0, so setting ${b_{j} = {\delta_{i\quad n} + \frac{1}{c_{1}} + {\frac{c_{2}}{c_{1}}\left( {j + \delta_{out}} \right)}}},$ dividing (14) through by c₁ we obtain $\begin{matrix} {{\left( {i + b_{j}} \right)g_{ij}} = {{\left( {i - 1 + \delta_{i\quad n}} \right)g_{{i - 1},j}} + {\frac{c_{2}\left( {j - 1 + \delta_{out}} \right)}{c_{1}}g_{i,{j - 1}}} + {\frac{\alpha}{c_{1}}{1_{\{{{i = 0},{j = 1}}\}}.}}}} & (16) \end{matrix}$ Using (16), it is not hard to show that g_(ij)=0 for all i>0 if αδ_(in)=0. For the moment, we therefore shall assume that αδ_(in)>0.

Note that, from the boundary condition, we have g_(i0)=0 for all i. Thus for j=1 the second term on the right of (16) disappears, and we see (skipping the details of the algebra) that $g_{i1} = {a\frac{\left( {i - 1 + \delta_{i\quad n}} \right)!}{\left( {i + b_{1}} \right)!}}$ where $a = {\alpha\frac{\left( {b_{1} - 1} \right)!}{{c_{1}\left( {\delta_{i\quad n} - 1} \right)}!}}$ is a positive constant. (Here we have used αδ_(in) >0.)

For j≧2 the last term in (16) is always zero. Solving for g_(ij) by iteration, we get $\begin{matrix} {g_{ij} = {\frac{c_{2}\left( {j - 1 + \delta_{out}} \right)}{c_{1}}{\sum\limits_{k = 0}^{i}\quad{\frac{\left( {i - 1 + \delta_{i\quad n}} \right)_{i - k}}{\left( {i + b_{j}} \right)_{i - k + 1}}{g_{k,{j - 1}}.}}}}} & (17) \end{matrix}$

Suppose that for some constants A_(jr) we have $\begin{matrix} {g_{ij} = {\sum\limits_{r = 1}^{j}\quad{A_{jr}\frac{\left( {i - 1 + \delta_{i\quad n}} \right)!}{\left( {i + b_{r}} \right)!}}}} & (18) \end{matrix}$ for all 1≦j≦j₀ and all i≧0. Note that we have shown this for j₀=1, with A₁₁=α. Let j=j₀+1. Then, using (17) and (18), we see that $\begin{matrix} {g_{ij} = {\sum\limits_{r = 1}^{j - 1}\quad{\frac{c_{2}\left( {j - 1 + \delta_{out}} \right)}{c_{1}}A_{{j - 1},r}{\sum\limits_{k = 0}^{i}\quad{\frac{\left( {i - 1 + \delta_{i\quad n}} \right)!}{\left( {i + b_{j}} \right)_{i - k + 1}{\left( {k + b_{r}} \right)!}}.}}}}} & (19) \end{matrix}$ Now it is straightforward to verify that if 0<y<x and s is an integer with 0≦s≦i+1, then $\begin{matrix} {{\sum\limits_{k = s}^{i}\quad\frac{1}{\left( {i + x} \right)_{i - k + 1}{\left( {k + y} \right)!}}} = {\frac{1}{x - y}{\left( {\frac{1}{\left( {i + y} \right)!} - \frac{\left( {s - 1 + x} \right)!}{{\left( {i + x} \right)!}{\left( {s - 1 + y} \right)!}}} \right).}}} & (20) \end{matrix}$ (For example one can use downwards induction on s starting from s=i+1 where both sides are zero.) Combining (19) and the s=0 case of (20) we see that $g_{ij} = {\sum\limits_{r = 1}^{j - 1}\quad{\frac{c_{2}\left( {j - 1 + \delta_{out}} \right)}{c_{1}}A_{{j - 1},r}\quad\frac{\left( {i - 1 + \delta_{i\quad n}} \right)!}{b_{j} - b_{r}}{\left( {\frac{1}{\left( {i + b_{r}} \right)!} - \frac{\left( {b_{j} - 1} \right)!}{{\left( {i + b_{j}} \right)!}{\left( {b_{r} - 1} \right)!}}} \right).}}}$ Collecting coefficients of 1/(i+b_(r))! for different values of r, and noting that b_(j)−b_(r)=(j−r)c₂/c₁, we see that (18) holds for j=j₀₊1, provided that ${{{for}\quad 1} \leq r \leq {j - 1}},\quad{{and}\quad\begin{matrix} {A_{jr} = {\frac{j - 1 + \delta_{out}}{j - r}A_{{j - 1},r}}} \\ {A_{jj} = {- {\sum\limits_{r = 1}^{j - 1}\quad{\frac{j - 1 + \delta_{out}}{j - r}\frac{\left( {b_{j} - 1} \right)!}{\left( {b_{r} - 1} \right)!}{A_{{j - 1},r}.}}}}} \end{matrix}}$ In fact we have the power law we are interested in (for g rather than f) without calculating the A_(jr). Observing only that A₁₁>0, so A_(j1)>0 for every j≧1, the r=1 term dominates (18). Thus for any fixed j>0 we have g _(ij) ˜C _(j) i′ ^(−1+δ) ^(in−b) ¹ =C _(j′) i ^(−/c) ^(+c) ² ^(/c) ¹ ^((1+δ) _(out)))  (21)

Having said that we do not need the A_(jr) for the power law, we include their calculation for completeness since it is straightforward. Skipping the rather unpleasant derivation, we claim that ${A_{jr} = {{a\left( {- 1} \right)}^{r - 1}\frac{\left( {j - 1 + \delta_{out}} \right)!}{{\delta_{out}!}{\left( {j - 1} \right)!}}\begin{pmatrix} {j - 1} \\ {r - 1} \end{pmatrix}\frac{\left( {b_{r} - 1} \right)!}{\left( {b_{1} - 1} \right)!}}},$ for the same constant a as above. This is easy to verify by induction on j using the relations above.

We now turn to h, for which the calculation is similar. From (15) we have $\begin{matrix} {{\left( {i + b_{j}} \right)h_{ij}} = {{\left( {i - 1 + \delta_{i\quad n}} \right)h_{i - {1j}}} + {\frac{c_{2}\left( {j - 1 + \delta_{out}} \right)}{c_{1}}h_{i,{j - 1}}} + {\frac{\gamma}{c_{1}}{1_{\{{{i = 1},{j = 0}}\}}.}}}} & (22) \end{matrix}$ Again skipping much of the algebra, for j=0 we see that h₀₀=0, while $h_{i0} = {{\gamma\frac{b_{0}!}{c_{1}{\delta_{i\quad n}!}}\frac{\left( {i - 1 + \delta_{i\quad n}} \right)!}{\left( {i + b_{0}} \right)!}\quad{for}\quad{all}\quad i} \geq 1.}$

If γδ_(out)=0, then h_(ij)=0 is zero for all j>0, so let us now assume γδ_(out)>0. This time the boundary condition implies that h_(0j)=0 for all j. For j≧1 we thus have from (22) that $h_{ij} = {\sum\limits_{k = 1}^{i}\quad{\frac{c_{2}\left( {j - 1 + \delta_{out}} \right)}{c_{1}}h_{k,{j - 1}}{\frac{\left( {i - 1 + \delta_{i\quad n}} \right)_{i - k}}{\left( {i + b_{j}} \right)_{i - k + 1}}.}}}$ (The only difference from (17) is that the sum starts with k=1.) Arguing as before, using the s=1 case of (20), we see that, for i≧1 and j≧0, ${h_{ij} = {\sum\limits_{r = 0}^{j}\quad{B_{jr}\frac{\left( {i - 1 + \delta_{i\quad n}} \right)!}{\left( {i + b_{r}} \right)!}}}},{where}$ $B_{jr} = {\left( {- 1} \right)^{r}\gamma\frac{\left( {j - 1 + \delta_{out}} \right)!}{{j!}{\left( {\delta_{out} - 1} \right)!}}\begin{pmatrix} j \\ r \end{pmatrix}{\frac{b_{r}!}{c_{1}{\delta_{i\quad n}!}}.}}$ (This makes sense as we are assuming that δ_(out)>0.) Here the r=0 term dominates, and we see that for each j≧0 we have h _(ij) ˜C _(j) ¹¹ i ^(−1δ) ^(in) ^(−b) ⁰ =C _(j) ¹¹ i ^(−(1+1/c) ¹ ^(+c) ² ^(δ) ^(out) ^(/c) ¹⁾   (23) as i→∞, for some positive constant C_(j) ¹¹. Returning now to f=g+h, considering j≧1 fixed and i→∞ we see that when γδ_(out)>0, the contribution from h dominates, while if Γδ_(out=)0, this contribution is zero. Thus combining (21) and (23) proves (11).

The second part of Theorem 2, the proof of (12), follows by interchanging in- and out-degrees, αand γ and δ_(in) and δ_(out). 

1. A computer-readable medium comprising computer-program instructions executable by a processor for modeling directed scale-free object relationships, the computer-program instructions comprising instructions for: generating a sequence of random numbers; and successively selecting individual ones of the random numbers over time to generate models of directed scale-free object relationships in a graph, with graph development depending on both in-degrees and out-degrees.
 2. A computer-readable medium as recited in claim 1, wherein the graph is a web graph comprising nodes and directed edges between respective ones of the nodes, the nodes corresponding to web pages and the directed edges corresponding to hyperlinks from one web page to another web page.
 3. A computer-readable medium as recited in claim 1, wherein the computer-program instructions further comprise instructions for successively using the random numbers to update the graph by: (A) adding an edge between a new object and an old object; (B) adding an edge between two old objects; or (C) adding an edge from an old object to a new object according to configurable parameters α, β and γ.
 4. A computer-readable medium as recited in claim 1, wherein the computer-program instructions further comprise instructions for adding new edges to the graph as a function of directed preferential attachment.
 5. A computer-readable medium as recited in claim 1, wherein the computer-program instructions further comprise instructions for generating the graph as a function of in-degree and/or out-degree shifts δ_(in), and/or δ_(out).
 6. A computer-readable medium as recited in claim 1, wherein the computer-program instructions further comprise instructions for modeling the graph as a function of a measured environmental characteristic based on a set of configurable parameters α, β, δ_(in) and δ_(out).
 7. A computer-readable medium as recited in claim 1, wherein an in-degree power law associated with an object represented by the graph is different from an out-degree power law associated with the object.
 8. A computer-readable medium as recited in claim 1, wherein an in-degree power law associated with an object represented by the graph is different from an out-degree power law associated with the object such that for a generator with parameters α, β, γ, δ_(out), a proportion of vertices with in-degree equal to di, asymptotically scales as follows: d_(i  n) − X_(i  n) with $X_{i\quad n} = {1 + \frac{1 + {\delta_{i\quad n}\left( {\alpha + \gamma} \right)}}{\alpha + \beta}}$ and a proportion of vertices with out-degree equal to d_(out) asymptotically scales as d_(out) − X_(out) with $X_{out} = {1 + {\frac{1 + {\delta_{out}\left( {\alpha + \gamma} \right)}}{\beta + \gamma}.}}$
 9. A computer-readable medium as recited in claim 3, wherein the computer-program instructions further comprise instructions based on (A) for updating the graph by adding an edge from a new object v to a random old object w chosen according to a probability distribution with Pr(w=w _(j))∝(d _(in)(w _(in))+δ_(in)).
 10. A computer-readable medium as recited in claim 3, wherein the computer-program instructions further comprise instructions based on (B), updating the graph by adding an edge from a first existing object v of the graph to a second existing object w, and wherein objects v and w are chosen according to a probability distribution with Pr(v=v _(i) ,w=w _(j))∝(d _(out)(v _(i))+δ_(out))(d _(in)(w _(j))+δ_(in)).
 11. A computer-readable medium as recited in claim 3, wherein the computer-program instructions further comprise instructions based on (C) for updating the graph by adding an edge from a randomly chosen old object w to a new object v, where w is chosen according to a probability distribution with Pr(w=w _(i))∝d _(out)(w _(i))+δ_(out).
 12. A computer-readable medium as recited in claim 3, wherein (A) the computer program instructions further comprise instructions for adding an edge E(i,j) from a new object v_(i) to an old object w_(j) by: dividing interval [0, t+nδ_(in)] into n slots of width d_(in)(w_(j))+δ_(in); selecting a random number r_(in) uniformly from the interval [0, t+nδ_(in)]; and selecting the old object w_(j) if the random number r_(in) falls into a j^(th) slot.
 13. A computer-readable medium as recited in claim 3, wherein the computer-program instructions based on (B) further comprise instructions for adding an edge E(i,j) from an old object v_(i) to an old object w_(j) by: dividing interval [0, t+nδ_(out)] into n slots of width d_(out)(v_(i))+δ_(out); selecting a random number r_(out) uniformly from the interval [0, t+nδ_(out)]; selecting the old object v_(i) if the random number r_(out) falls into an i^(th) slot; dividing interval [0, t+nδ_(in)] into n slots of width d_(in) (w_(j))+δ_(in); selecting a random number r_(in) uniformly from the interval [0, t+nδ_(in)]; and selecting the old object w_(j) if the random number r_(in) falls into a j^(th) slot.
 14. A computer-readable medium as recited in claim 3, wherein the computer program instructions based on (C) further comprise instructions for adding an edge E(i,j) from an old object w_(i) to a new object v_(j) by: dividing interval [0, t+nδ_(out)] into n slots of width d_(out)(w_(i))+δ_(out); selecting a random number r_(out) uniformly from the interval [0, t+nδ_(out)]; and selecting the old object w_(i) if the random number r_(out) falls into an i^(th) slot.
 15. A computer-readable medium as recited in claim 1, wherein the computer-program instructions further comprise instructions for: independently generating two random numbers λ(v) and μ(v) from specified distributions D_(in) and D_(out) for a new vertex v of the graph; and utilizing the random numbers to update vertices of the graph as follows: (A) choosing an existing vertex w according to λ(w)(d_(in)+δ_(in)) such that Pr(w=w_(j))∝λ/(w_(j))(d_(in)(w_(j))+δ_(in)); (B) choosing an existing vertex v according to μ(v)(d_(out)+δ_(out)) and a second existing vertex w according to λ(w)(d_(in)+δ_(in)) so that Pr(v=v_(i), w=w_(j))∝μ(v_(i))λ(w_(j))(d_(out)(v_(i))+δ_(out))(d_(in)(w_(j))+δ_(in)); or (C) selecting an existing vertex w according to μ(w)(d_(out)+δ_(out)) such that Pr(w=w_(i))∝μ(w_(i))(d_(out)(w_(i))+δ_(out)).
 16. A method to generate models of directed scale-free object relationships, the method comprising: generating a sequence of random numbers; and successively selecting individual ones of the random numbers over time to generate models of directed scale-free object relationships in a graph, with the development of the graph depending on both in-degrees and out-degrees.
 17. A method as recited in claim 16, wherein the graph is a web graph comprising nodes and directed edges between respective ones of the nodes, the nodes corresponding to web pages and the directed edges corresponding to hyperlinks from one web page to another web page.
 18. A method as recited in claim 16, wherein the method further comprises successively using the random numbers to update the graph by: (A) adding an edge between a new object and an old object; (B) adding an edge between two old objects; or (C) adding an edge from an old object to a new object according to configurable parameters α, β and γ.
 19. A method as recited in claim 16, wherein the method further comprises adding new edges to the graph as a function of directed preferential attachment.
 20. A method as recited in claim 16, wherein the method further comprises generating the graph as a function of in-degree and/or out-degree shifts δ_(in) and/or δ_(out).
 21. A method as recited in claim 16, wherein the method further comprises modeling the graph as a function of a measured environmental characteristic that is based on a set of configurable parameters α, β, γ, δ_(in), and δ_(out).
 22. A method as recited in claim 16, wherein an in-degree power law associated with an object represented by the graph is different from an out-degree power law associated with the object.
 23. A method as recited in claim 16, wherein an in-degree power law associated with an object represented by the graph is different from an out-degree power law associated with the object such that for a generator with parameters α, β, γ, δ_(in) and δ_(out), a proportion of vertices with in-degree equal to d_(in) asymptotically scales as follows: d_(i  n) − X_(i  n) with $X_{i\quad n} = {1 + \frac{1 + {\delta_{i\quad n}\left( {\alpha + \gamma} \right)}}{\alpha + \beta}}$ and a proportion of vertices with out-degree equal to d_(out) asymptotically scales as d_(out) − X_(out) with $X_{out} = {1 + {\frac{1 + {\delta_{out}\left( {\alpha + \gamma} \right)}}{\beta + \gamma}.}}$
 24. A method as recited in claim 18, wherein (A) further comprises updating the graph by adding an edge from a new object v to a random old object w being chosen according to a probability distribution with Pr(w=w _(j))∝(d _(in)(w _(j))+δ_(in)).
 25. A method as recited in claim 18, wherein (B) further comprises updating the graph by adding an edge from a first existing object v of the graph to a second existing object w where the objects v and w are chosen according to a probability distribution with Pr(v=v _(i) ,w=w _(j))∝(d _(out)(v _(i))+δ_(out))(d _(in)(w _(j))+δ_(in)).
 26. A method as recited in claim 18, wherein (C) further comprises updating the graph by adding an edge from a randomly chosen old object w to a new object v, where w is chosen according to a probability distribution with Pr(w=w _(i))∝d _(out)(w _(i))+δ_(out).
 27. A method as recited in claim 24, wherein (A) further comprises adding an edge E(i,j) from a new object v_(i) to an old object w_(j) by: dividing interval [0, t+nδ_(in)] into n slots of width d_(in)(w_(j))+δ_(in); selecting a random number r_(in) uniformly from the interval [0, t+nδ_(in)]; and selecting the old object w_(j) if the random number r_(in) falls into a j^(th) slot.
 28. A method as recited in claim 25, wherein (B) further comprises adding an edge E(i,j) from an old object v_(i) to a second old object w_(j) by: dividing the interval [0, t+nδ_(out)] into n slots of width d_(out)(v_(i))+δ_(out); selecting a random number r_(out) uniformly from the interval [0, t+nδ_(out)]; selecting the old object v_(i) if the random number r_(out) falls into an i^(th) slot; dividing the interval [0, t+nδ_(in)] into n slots of width d_(in) (w_(j))+δ_(in); selecting a random number r_(in) uniformly from the interval [0, t+nδ_(in)]; and selecting the old object w_(j) if the random number r_(in) falls into a j^(th) slot.
 29. A method as recited in claim 26, wherein (C) further comprises adding an edge E(i,j) from an old object w_(i) to a new object v_(j) by: dividing the interval [0, t+nδ_(out)] into n slots of width d_(out)(w_(i))+δ_(out); selecting a random number r_(out) uniformly from the interval [0, t+nδ_(out)]; and selecting the old object w_(i) if the random number r_(out) falls into an i^(th) slot.
 30. A method as recited in claim 16, wherein the method further comprises: independently generating two random numbers λ(v) and λ(v) from specified distributions D_(in) and D_(out) for a new vertex v of the graph; and utilizing the random numbers to update vertices of the graph as follows: (A) choosing an existing vertex w according to λ(w)(d_(in)+δ_(in)) such that Pr(w=w_(j))∝λ(w_(j))(d_(in)(w_(j))+δ_(in)); (B) choosing an existing vertex v according to μ(v)(d_(out)+δ_(out)) and a second existing vertex w according to λ(w)(d_(in)+δ_(in)), so that Pr(v=v_(i), w=w_(j))∝μ(v_(i))λ(w_(j))(d_(out)(v_(i))+δ_(out))(d_(in)(w_(j))+δ_(in)); or (C) selecting an existing vertex w according to μ(w)(d_(out)+δ_(out)) such that Pr(w=w_(i))∝μ(w_(i)(d_(out)(w_(i))+δ_(out)).
 31. A computing device for generating models of directed scale-free object relationships, the computing device comprising: a processor; and a memory coupled to the processor, the memory comprising computer-program instructions executable by the processor for: generating a sequence of random numbers; and successively selecting individual ones of the random numbers over time to generate models of directed scale-free object relationships in a graph, with the development of the graph depending on both in-degrees and out-degrees.
 32. A computing device as recited in claim 31, wherein the graph is a web graph comprising nodes and directed edges between respective ones of the nodes, the nodes corresponding to web pages and the directed edges corresponding to hyperlinks from one web page to another web page.
 33. A computing device as recited in claim 31, wherein the computer-program instructions further comprise instructions for successively using the random numbers to update the graph by: (A) adding an edge between a new object and an old object; (B) adding an edge between two old objects; or (C) adding an edge from an old object to a new object according to configurable parameters α, β and γ.
 34. A computing device as recited in claim 31, wherein the computer-program instructions further comprise instructions for adding new edges to the graph as a function of directed preferential attachment.
 35. A computing device as recited in claim 31, wherein the computer-program instructions further comprise instructions for generating the graph as a function of in-degree and/or out-degree shifts δ_(in) and/or δ_(out).
 36. A computing device as recited in claim 31, wherein the computer-program instructions further comprise instructions for modeling the graph as a function of a measured environmental characteristic that is based on a set of configurable parameters α, β, γ, δ_(in), and δ_(out).
 37. A computing device as recited in claim 31, wherein an in-degree power law associated with an object represented by the graph is different from an out-degree power law power law associated with the object.
 38. A computing device as recited in claim 31, wherein an in-degree power law associated with an object represented by the graph is different from an out-degree power law associated with the object such that for a generator with parameters α, β, γ, δ_(in) and δ_(out), a proportion of vertices with in-degree equal to d_(in) asymptotically scales as follows: d_(i  n) − X_(i  n) with $X_{i\quad n} = {1 + \frac{1 + {\delta_{i\quad n}\left( {\alpha + \gamma} \right)}}{\alpha + \beta}}$ and a proportion of vertices with out-degree equal to d_(out) asymptotically scales as d_(out) − X_(out) with $X_{out} = {1 + {\frac{1 + {\delta_{out}\left( {\alpha + \gamma} \right)}}{\beta + \gamma}.}}$
 39. A computing device as recited in claim 33, wherein the computer-program instructions further comprise instructions based on (A) for updating the graph by adding an edge from a new object v to a random old object w chosen according to a probability distribution with Pr(w=w _(j))∝(d _(in)(w _(j))+δ_(in)).
 40. A computing device as recited in claim 33, wherein the computer-program instructions further comprise instructions based on (B), updating the graph by adding an edge from a first existing object v of the graph to a second existing object w where the objects v and w are chosen according to a probability distribution with Pr(v=v _(i) ,w=w _(j))∝(d _(out)(v _(i))+δ_(out))(d _(in)(w _(j))+δ_(in)).
 41. A computing device as recited in claim 33, wherein the computer-program instructions further comprise instructions based on (C) for updating the graph by adding an edge from a randomly chosen old object w to a new object v, where w is chosen according to a probability distribution with Pr(w=w _(i))∝d _(out)(w _(i))+δ_(out).
 42. A computing device as recited in claims 33 and 39, wherein the computer-program instructions based’ on (A) further comprise instructions for adding an edge E(i,j) from a new object v_(i) to an old object w_(j) by: dividing interval [0, t+nδ_(in)] into n slots of width d_(in)(w_(j))+δ_(in); selecting a random number r_(in) uniformly from the interval [0, t+nδ_(in)]; and selecting the old object w_(j) if the random number r_(in) falls into a j^(th) slot.
 43. A computing device as recited in claims 33 and 40, wherein the computer-program instructions based on (B) further comprise instructions for adding an edge E(i,j) from an old object v_(i) to a second old object w_(j) by: dividing the interval [0, t+nδ_(out)] into n slots of width d_(out)(v_(i))+δ_(out); selecting a random number r_(out) uniformly from the interval [0, t+nδ_(out)]; selecting the old object v_(i) if the random number r_(out) falls into an i^(th) slot; dividing the interval [0, t+nδ_(in)] into n slots of width d_(in)(w_(j))+δ_(in); selecting a random number r_(in) uniformly from the interval [0, t+nδ_(in)]; and selecting the old object w_(j) if the random number r_(in) falls into a j^(th) slot.
 44. A computing device as recited in claim 33 and 41, wherein the computer program instructions based on (C) further comprise instructions for adding an edge E(i,j) from an old object w_(i) to a new object v_(j) by: dividing the interval [0, t+nδ_(out)] into n slots of width d_(out)(w_(i))+δ_(out); selecting a random number r_(out) uniformly from the interval [0, t+nε_(out)]; and selecting the old object w_(i) if the random number r_(out) falls into an i^(th) slot.
 45. A computing device as recited in claim 31, wherein the computer-program instructions further comprise instructions for: independently generating two random numbers λ(v) and μ(v) from specified distributions D_(in) and D_(out) for a new vertex v of the graph; and utilizing the random numbers to update vertices of the graph as follows: (A) choosing an existing vertex w according to λ(w)(d_(in)+δ_(in)) such that Pr(w=w_(j))∝λ(w_(j))(d_(in)(w_(j))+δ_(in)); (B) choosing an existing vertex v according to μ(v)(d_(out)+δ_(out)) and a second existing vertex w according to λ(w)(d_(in)+δ_(in)) so that Pr(v=v_(i), w=w_(j))∝μ(v_(i))λ(w_(j))(d_(out)(v_(i))+δ_(out))(d_(in)(w_(j))+(δ_(in)); or (C) selecting an existing vertex w according to μ(w)(d_(out)+δ_(out)) such that Pr(w=w_(i))∝μ(w_(i))(d_(out)(w_(i))+δ_(out)).
 46. A computing device for generating models of directed scale-free object relationships, the computing device comprising: means for generating a sequence of random numbers; means for successively selecting individual ones of the random numbers over time to generate models of directed scale-free object relationships in a graph, with the development of the graph depending on both in-degrees and out-degrees.
 47. A computing device as recited in claim 46, wherein the graph is a web graph comprising nodes and directed edges between respective ones of the nodes, the nodes corresponding to web pages and the directed edges corresponding to hyperlinks from one web page to another web page.
 48. A computing device as recited in claim 46, and further comprising means for successively using the random numbers to update the graph by: (A) adding an edge between a new object and an old object; (B) adding an edge between two old objects; or (C) adding an edge from an old object to a new object, according to configurable parameters (α, β and γ.
 49. A computing device as recited in claim 46, and further comprising means for adding new edges to the graph as a function of directed preferential attachment.
 50. A computing device as recited in claim 46, and further comprising means for generating the graph as a function of in-degree and/or out-degree shifts δ_(in) and/or δ_(out).
 51. A computing device as recited in claim 46, and further comprising means for modeling the graph as a function of a measured environmental characteristic that is based on a set of configurable parameters α, β, γ, δ_(in) and δ_(out).
 52. A computing device as recited in claim 46, wherein an in-degree power law associated with an object represented by the graph is different from an out-degree power law power law associated with the object.
 53. A computing device as recited in claim 46, wherein an in-degree power law associated with an object represented by the graph is different from an out-degree power law associated with the object such that for a generator with parameters α, β, γ, δ_(in) and δ_(out), a proportion of vertices with in-degree equal to d_(in) asymptotically scales as follows: d_(i  n) − X_(i  n) with $X_{i\quad n} = {1 + \frac{1 + {\delta_{i\quad n}\left( {\alpha + \gamma} \right)}}{\alpha + \beta}}$ and a proportion of vertices with out-degree equal to d_(out) asymptotically scales as d_(out) − X_(out) with $X_{out} = {1 + {\frac{1 + {\delta_{out}\left( {\alpha + \gamma} \right)}}{\beta + \gamma}.}}$
 54. A computing device as recited in claim 48, and further comprising means based on (A) for updating the graph by adding an edge from a new object v to a random old object w chosen according to a probability distribution with Pr(w=w _(j))∝(d _(in)(w _(j))+δ_(in)).
 55. A computing device as recited in claim 48, and further comprising means based on (B), updating the graph by adding an edge from a first existing object v of the graph to a second existing object w where the objects v and w are chosen according to a probability distribution with Pr(v=v _(i) ,w=w _(j))∝(d _(out)(v _(i))+δ_(out))(d _(in)(w _(j))+δ_(in)).
 56. A computing device as recited in claim 48, and further comprising means based on (C) for updating the graph by adding an edge from a randomly chosen old object w to a new object v, where w is chosen according to a probability distribution with Pr(w=w _(i))∝d _(out)(w _(i))+δ_(out).
 57. A computing device as recited in claim 48, and further comprising means based on (A) for adding an edge E(i,j) from a new object v_(i) to an old object w_(j) by: dividing interval [0, t+nδ_(in)] into n slots of width d_(in)(w_(j))+δ_(in); selecting a random number r_(in) uniformly from the interval [0, t+nδ_(in)]; and selecting the old object w_(j) if the random number r_(in) falls into a j^(th) slot.
 58. A computing device as recited in claim 48, and further comprising means based on (B) for adding an edge E(i,j) from an old object v_(i) to a second old object w_(j) by: dividing the interval [0, t+nδ_(out)] into n slots of width d_(out)(v_(i))+δ_(out); selecting a random number r_(out) uniformly from the interval [0, t+nδ_(out)]; selecting the old object v_(i) if the random number r_(out) falls into an i^(th) slot; dividing the interval [0, t+nδ_(in)] into n slots of width d_(in) (w_(j))+δ_(in); selecting a random number r_(in) uniformly from the interval [0, t+nδ_(in)]; and selecting the old object w_(j) if the random number r_(in) falls into a j^(th) slot.
 59. A computing device as recited in claim 48, and further comprising means based on (C) for adding an edge E(i,j) from an old object w_(i) to a new object v_(j) by: dividing the interval [0, t+nδ_(out)] into n slots of width d_(out)(w_(i))+δ_(out); selecting a random number r_(out) uniformly from the interval [0, t+nδ_(out)]; and selecting the old object w_(i) if the random number r_(out) falls into an i^(th) slot.
 60. A computing device as recited in claim 46, and further comprising means for: independently generating two random numbers λ(v) and μ(v) from specified distributions D_(in) and D_(out) for a new vertex v of the graph; and utilizing the random numbers to update vertices of the graph as follows: (A) choosing an existing vertex w according to λ(w)(d_(in)+δ_(in)) such that Pr(w=w_(j))∝λ(w_(j))(d_(in)(w_(j))+δ_(in)); (B) choosing an existing vertex v according to μ(v)(d_(out)+δ_(out)) and a second existing vertex w according to λ(w)(d_(in)+δ_(in)), so that Pr(v=v_(i), w=w_(j))∝μ(v_(i))λ(w_(j))(d_(out)(v_(i))+δ_(out))(d_(in)(w_(j))+δ_(in)); or (C) selecting an existing vertex w according to μ(w)(d_(out)+δ_(out)) such that Pr(w=w_(i))∝μ(w_(i)(d_(out)(w_(i))+δ_(out)). 